Cyclonic vacuum cleaner with improved collection chamber

ABSTRACT

A vacuum cleaner with a cyclone module assembly comprises a cyclone separation chamber for separating dust and debris from air and a collection chamber for collecting dust and debris that is separated from the air in the cyclone separation chamber. The cyclone module assembly further includes at least one feature for directing contaminants downwardly, such as a circumferential fin that extends from the inside wall of the collection chamber.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a divisional of U.S. patent application Ser. No.13/958,963, filed Aug. 5, 2013, which is a divisional of U.S. patentapplication Ser. No. 12/478,421, filed Jun. 4, 2009, now U.S. Pat. No.8,499,411, issued Aug. 6, 2013, which claims the benefit of U.S.Provisional Patent Application No. 61/058,995, filed Jun. 5, 2008, bothof which are incorporated herein by reference in their entirety.

BACKGROUND OF THE INVENTION

Field of the Invention

The invention relates to suction cleaners, and in particular to suctioncleaners having cyclonic dirt separation. In one of its aspects, theinvention relates to an improved collection chamber configured toprevent debris re-entrainment.

Description of the Related Art

Upright vacuum cleaners employing cyclone separators are well known.Some cyclone separators follow textbook examples using frusto-conicalshape separators and others use high-speed rotational motion of theair/dirt to separate the dirt by centrifugal force. Typically, workingair enters and exits at an upper portion of the cyclone separator as thebottom portion of the cyclone separator is used to collect debris.Furthermore, in an effort to reduce weight, the motor/fan assembly thatcreates the working air flow is typically placed at the bottom of thehandle, below the cyclone separator.

U.S. Pat. No. 6,810,557 to Hansen et al. discloses an upright vacuumcleaner that has a cyclone separator and a dirt cup. A horizontal plateseparates the cyclone separator from the dirt cup. The air flowingthrough the cyclone separator passes through an annular cylindrical cagewith baffles and through a cylindrical filter before exiting the cycloneseparator at the upper end thereof. The dirt tank has fins that projectvertically from a sidewall and from the bottom wall to reducere-entrainment of dirt particles. This patent is incorporated herein byreference in its entirety.

EP 0 728 435 to Black & Decker discloses a cyclone dust extractor thathas a cyclone separator and a dust collector that is below and separablefrom the cyclone separator. A cylindrical collar extends inwardly anddownwardly from a lower portion of the inner surface of the side wall ofthe dust collector and against which is said large dust and debrisparticles collide, thereby assisting in removing the dust and debrisfrom the air flow and depositing it in the dust collector. These dustand debris particle will accumulate in the inverted pocket formed by thecollar when the dust collector is inverted to empty the dust and debrisfrom the dust collector. A similar construction is disclosed in the OhU.S. Pat. No. 6,502,278.

SUMMARY OF THE INVENTION

According to another aspect of the invention, a vacuum cleaner comprisesa cyclone separator having a separator chamber for separatingcontaminants from a dirt-containing airstream, and further comprising aninlet and an outlet in fluid communication with the separator chamber, acollection chamber associated with the cyclone separator for receivingcontaminants separated in the separator chamber and having a sidewalland a bottom wall, a suction nozzle fluidly connected with the inlet; asuction source fluidly connected to the suction nozzle and to theseparator chamber for establishing and maintaining a dirt-containingairstream from the suction nozzle to the inlet, and a singlecircumferential fin extending inwardly from the sidewall of thecollection chamber, wherein the fin is configured to reduce debrisre-entrainment in the collection chamber.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings:

FIG. 1 is a perspective view of an upright vacuum cleaner having acyclone module assembly with an improved dirt cup according to a firstembodiment of the invention.

FIG. 2 is an exploded right front quarter perspective view of thecyclone module assembly of FIG. 1.

FIG. 3 is a cross-sectional view of the cyclone module assembly takenthrough line 3-3 of FIG. 2

FIG. 4A is a partial cut-away perspective view of the dirt cup shown inFIG. 1.

FIG. 4B is a top view of the dirt cup assembly shown in FIG. 4A.

FIG. 4C is a top view of a dirt cup assembly according to a secondembodiment of the invention.

FIG. 4D is a top view of a dirt cup assembly according to a thirdembodiment of the invention.

FIG. 4E is a cross-sectional view of a cyclone module assembly accordingto a fourth embodiment of the invention.

FIG. 5 is a partial exploded view of a filter cartridge and a filterhousing of the upright vacuum cleaner shown in FIG. 1

FIG. 6 is a cross-sectional view of the filter housing and a motorhousing of the upright vacuum cleaner taken through line 6-6 of FIG. 5.

FIG. 7 is an exploded perspective view of a cyclone module assemblyaccording to a fifth embodiment of the invention.

FIG. 8 is a cross-sectional view of the cyclone module assembly takenthrough line 8-8 of FIG. 7.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to the drawings, and in particular to FIG. 1, an uprightvacuum cleaner 10 comprises an upright handle assembly 12 pivotallymounted to a foot assembly 14. The handle assembly 12 further comprisesa primary support section 16 with a grip 18 on one end to facilitatemovement by a user. A motor cavity 20 is formed at an opposite end ofthe handle assembly 12 to contain a conventional suction source such asa vacuum fan/motor assembly 22 (FIG. 6) oriented transversely therein. Afilter housing 24 is formed above the motor cavity 20 and is in fluidcommunication with the vacuum fan/motor assembly 22. The handle assembly12 pivots relative to the foot assembly 14 through a pivot axis that iscoaxial with a motor shaft (not shown) associated with the vacuumfan/motor assembly 22. A recess 40 on the primary support section 16 ofthe handle assembly 12 receives a cyclone module assembly 42 accordingto a first embodiment of the invention.

The foot assembly 14 comprises a lower housing 26 that mates with anupper housing 28 to form a brush chamber 30 therebetween. While notshown, a rotating brush roll assembly can be positioned within the brushchamber 30 and operably connected to the motor shaft of the vacuumfan/motor assembly 22 (FIG. 6) via a stretch belt as is common in thevacuum cleaner art. Rear wheels 34 are secured to a rearward portion ofthe foot assembly 14 and a pair of support wheels (not shown) aresecured to the foot assembly 14 between the brush chamber 30 and rearwheels 34 for moving the foot assembly 14 over a surface to be cleaned.A suction nozzle 38 is formed at a lower surface of the brush chamber 30on the foot assembly 14 and is in fluid communication with the vacuumfan/motor assembly 22.

Referring to FIGS. 2 through 4B, the cyclone module assembly 42 of thefirst embodiment further comprises a cyclone separator 50 for separatingcontaminants from a dirt-containing airstream and a dirt cup assembly 66for receiving contaminants separated by the cyclone separator 50. Thecyclone separator 50 includes a first stage cyclone housing 56 defining,in part, a first stage separator chamber 48, and an inner second stagecyclone housing 52 defining, in part, a second stage separator chamber46. The first stage cyclone housing 56 comprises a generally cylindricalouter wall 62 having an upper wall 61 forming a closed top and an openbottom, a cyclone inlet 57 formed in the outer wall 62 and a cycloneoutlet 59 formed on the upper wall 61. A first stage debris outlet 58 isformed by a gap between a separator plate 60 and the outer wall 62. Theseparator plate 60 separates the first stage separator chamber 48 fromthe dirt cup assembly 66.

As shown in FIG. 3, the frusto-conical shaped second stage cyclonehousing 52 depends from the upper wall 61 of the first stage cyclonehousing 56 and includes an upper cylindrical portion 65 and a lowerfrusto-conical portion 67 which mounts the separator plate 60. A pair ofopposed inlets 63 are formed in the cylindrical portion 65 and a seconddebris outlet 64 is formed in the bottom of the frusto-conical portion67.

A grill assembly 54 is positioned around the cylindrical portion 65 andseparates the first stage separator chamber 48 from the second stageseparator chamber 46. The grill assembly 54 includes an outer perforatedwall 176 and an inner wall forming a vortex finder 174. The vortexfinder 174 defines a second stage outlet aperture 172 that is in fluidcommunication with the cyclone outlet 59.

The dirt cup assembly 66 comprises a dirt cup housing 68 having an outerhousing wall 78 and an inner housing wall 79 spaced from the outerhousing wall 78 in concentric relation. A first stage collection chamber70 is formed between the housing walls 78, 79 and a second stagecollection chamber 72 is formed within the inner housing wall 79 and issealed off from the first stage collection chamber 70. The dirt cupassembly 66 sealingly mates with the cyclone separator 50 via a lip 74formed on a lower surface of the outer wall 62. A first gasket 71 ispositioned between the lip 74 and the upper edge of the outer housingwall 78. The inner housing wall 79 sealingly mates with a lower surfaceof the second stage cyclone housing 52 such that the second debrisoutlet 64 is in fluid communication with the second stage collectionchamber 72 and isolated from the first stage debris outlet 58. A secondgasket 73 is positioned between the separator plate 60 and the upperedge of the inner housing wall 79.

The dirt cup assembly 66 further comprises at least one circumferentialfin 76 that extends inwardly from an interior surface of the outerhousing wall 78. The fin 76 functions to direct or urge debris to thebottom of the collection chamber 70 and keep the separated debriscontained in the first stage collection chamber 70. Each fin 76comprises a leading end 80 and a trailing end 82 and has an outer edge83 that is attached to the outer housing wall 78 and an inner arcuateedge 84 that is free. In terms of the working air flow, the leading end80 of each fin 76 is upstream of the trailing end 82. Optionally, thearcuate edge 84 conforms to the shape of the outer housing wall 78 andcan be parallel to the outer housing wall 78.

In the illustrated embodiment, multiple intermittently spaced fins 76are employed. Four spaced fins are shown in FIGS. 2 and 4B. Each fin 76extends in a perpendicular radial direction from the housing outer wall78 but is preferably oriented in a circumferential direction at anoblique angle with respect to the horizontal, with the leading end 80vertically spaced above the trailing end 82. Furthermore, adjacent fins76 can be arranged in a helical fashion, i.e. along a helical trajectoryand furthermore can be vertically staggered such that the leading end 80of a first fin 76 is vertically spaced from the trailing end 82 of asecond, adjacent fin 76. However, each fin 76 extends horizontallyinwardly from the outer wall 78 toward the center of the dirt cuphousing 68.

The fins 76 can have a length L of approximately 1.0 to 6.0 inches (25.4to 152.4 mm), a width W of approximately 0.125 to 1.0 inches (about 3 to25 mm) wide, and a thickness T of approximately 0.040 to 0.125 inches(about 1 to 3 mm). More specifically, the fins 76 can have a length L ofapproximately 3.0 inches (about 76 mm), a width W of approximately ⅜inches (about 9-10 mm) wide, and a thickness T of approximately 1/16inches (about 1-2 mm). It has been discovered that a combination of thegiven specific dimensions for the length L, width W, and thickness T,and spacing the fins 67 intermittently in a helical fashion such thatthe leading end 80 is above the trailing end 82 achieves the bestseparation efficiency, i.e. the most debris separation coupled with theleast re-entrainment of debris. The lateral spacing S between fins 76can measure from about 0.25 inches (about 6-7 mm) to about 4.0 inches(about 100 mm); however, a preferred distance is about 1.25 inches(about 32 mm). The lateral spacing S between the fins 76 facilitatesdebris removal as will be described in more detail. Optionally, thedifference in height H₁ between the leading end 80 and the trailing end82 of one of the fins 76 can range from 0.125 to 2.0 inches (about 3 to51 mm) or be approximately 0.5 inches (about 12.5-13 mm). Furthermore,adjacent fins 76 can optionally be staggered vertically relative to eachother such that the difference in height H2 between the leading end 80of a first fin 76 and the trailing end 82 of a second, adjacent fin 76is in the range of 0.125 to 2.0 inches (about 3 to 51 mm), preferablyapproximately 0.5 inches (12.5-13.0 mm).

Referring to FIG. 4C, a dirt cup assembly 66′ according to a secondembodiment of the invention is shown. The dirt cup assembly 66′ issubstantially identical to the dirt cup assembly 66 shown in FIG. 4B,except for the fin arrangement, which comprises three intermittentlyspaced fins 76′.

Referring to FIG. 4D, a dirt cup assembly 66″ according to a thirdembodiment of the invention is shown. The dirt cup assembly 66″ issubstantially identical to the dirt cup assembly 66 shown in FIG. 4B,except for the fin arrangement, which comprises a single fin 76″. Thefin 76″ can extend in a helical or spiral fashion around the outerhousing wall 78″. Optionally, the fin 76″ can extend less than 360°around the circumference of the wall 78″ so that the leading end 80″does not overlap the trailing end 82″ or the fin 76″ can extend morethan 360° around the circumference of the wall 78″ so that the leadingend 80″ overlaps the trailing end 82″. Alternately, as illustratedherein, the fin 76″ can extend approximately 360° around thecircumference of the wall 78″ such that the leading end 80″ and thetrailing end 82″ lie along a common plane.

Referring to FIG. 4E, a cyclone module assembly 42 according to a fourthembodiment of the invention is shown. The cyclone module assembly 42 issubstantially identical to the cyclone module assembly 42 shown in FIG.3, except for the fin arrangement, and like elements will be referred towith like reference numerals. As illustrated, the third embodimentcomprises at least one partial circumferential fin 184 that extendshorizontally inwardly from an interior surface of the outer housing wall78 and functions to direct or urge debris to the bottom of thecollection chamber 70 and keep the separated debris contained in thefirst stage collection chamber 70. Each fin 184 is discontinuous in thatit extends only partially around the circumference of the collectionchamber 70 and comprises a leading end 186 and a trailing end 188. Interms of the working air flow, the leading end 186 of each fin 184 isupstream of the trailing end 188.

In the illustrated embodiment, multiple intermittently spaced fins 184are employed. Two fins 184 are visible in FIG. 4E, but is envisionedthat 3 or more fins can be employed with this embodiment. Each fin 184is preferably oriented horizontally, with the leading end 186 and thetrailing end 188 lying along a common horizontal plane. In addition,each fin 184 extends radially in a perpendicular direction (orhorizontally) from the outer wall 78 toward the center of the dirt cuphousing 68 so that dust and debris does not accumulate under the spacedfins when the collection chamber 70 is inverted for emptying. Althoughnot shown, each fin 184 can extend inwardly and upwardly at an acuteangle to the outer wall 78, if desired. The intermittently spaced fins184 also provide slightly improved efficiency of separation and ease ofdumping the dust and debris than annular fins as, for example,illustrated in the prior art references cited above. Furthermore,adjacent fins 184 can be vertically staggered so that the leading end186 of a first fin 184 is vertically spaced from the trailing end 188 ofa second, adjacent fin 184. The fins 184 can have the same dimensionsgiven above for the first embodiment, except that the fins 184 will nothave a height H₁ since the leading end 186 and trailing end 188 liealong a common horizontal plane.

As shown in FIGS. 5 and 6, the vacuum fan/motor assembly 22 comprises amotor assembly 85 and a fan assembly 86. The vacuum fan/motor assembly22 further includes a fan chamber 89 in fluid communication with aworking air inlet 91 and a working air outlet 93. The motor assembly 85includes a motor cooling air inlet 95 and a motor cooling air outlet 97.

The filter housing 24 comprises a filter compartment 88 having adividing wall 90 that separates the filter compartment 88 into a workingair inlet region 92 and a working air outlet region 96 that is separatefrom the working air inlet region 92. The working air inlet region 92fluidly communicates a working air conduit 94, which is in fluidcommunication with the cyclone outlet 59 (FIG. 2) with the working airinlet 91 of the fan chamber 89 after passing the working air through apre-motor filter. The working air outlet region 96 fluidly communicatesthe motor cooling outlet 97 with the external atmosphere after passingthe working air through an exhaust filter.

A substantially disk shaped filter cartridge or assembly 98 is sealedwithin the filter compartment 88. In one embodiment, the filter assembly98 comprises a substantially rigid filter frame 100 comprising avertical annular wall 102 formed in a circular shape, with a dividingwall 104, which can be substantially aligned with the dividing wall 90,formed across the center thereof to divide the filter frame 100 into twodistinct regions; a pre-motor filter region 106 and an exhaust filterregion 108. The pre-motor filter region 106 and exhaust filter region108 are bounded by a section of the annular wall 102 and the dividingwall 104 and have a semi-circular shape. The pre-motor filter region 106preferably receives a commonly known filter media 110 such as open cellfoam or other known suitable material that is formed to fit thesemi-circular shape of the region 106. The exhaust filter region 108preferably receives known filter media 112 such as pleated paper, HEPAmedia, pleated HEPA media, non-woven filter media, or the like, and isalso formed in a semi-circular shape. Optionally the filter media 110can be removable from the filter frame 100 and that filter media 112 canbe sealed to the filter frame 100 with a suitable sealant such assilicone or the like. A filter cover 114 is sealingly fixed to the topsurface of the filter frame 100 and seals each distinct filter region106, 108 from the other. The filter cover 114 comprises a plurality ofexhaust apertures 116 above the exhaust filter region 108 in fluidcommunication with the external atmosphere. The filter cover 114 ispreferably user removable via a commonly known twist lock latch 118 orother mechanism such as a hinged cover with retaining latch to alloweasy user-access to the filter media 110, 112 for replacing or cleaningthereof. The filter cover 114 can also include a keying feature (notshown) to permit only a unique orientation of the cover 114 on thefilter frame 100.

Referring to FIGS. 3 and 6, in which the flow path of air is indicatedby arrows, the operation of the separators will be described. The vacuumfan/motor assembly 22 is positioned downstream of the cyclone outlet 59such that when energized, establishes and maintains a dirt-containingairstream from the suction nozzle 38 to the cyclone separator 50. Thevacuum fan/motor assembly 22 draws air from the suction nozzle 38(FIG. 1) to the cyclone inlet 57 and into the cyclone separator 50 wherethe dirty air to swirls around the first stage separator chamber 48.Larger debris falls into the first stage collection chamber 70 of thedirt cup assembly 66 via the gap 58. The intermittently spaced fins 76force the debris to the bottom of the collection chamber 70 and keep theseparated debris contained in the first stage collection chamber 70. Theworking air then passes through the outer perforated wall 176 of thegrill assembly 54 to filter out any remaining large debris and entersthe second stage separator chamber 46 via the second stage inlet inlets63. The second stage inlets 63 direct the air tangentially anddownwardly along an inside surface of the second stage cyclone housing52. The airflow turns near the second stage debris outlet 64 andproceeds directly upward to the second stage outlet aperture 172 andthrough the cyclone outlet 59. The dirt removed in the second stageseparator chamber 46 falls into the second stage collection chamber 72.

From the cyclone outlet 59, the working air travels through the workingair conduit 94 and is delivered to the pre-motor filter region 106 ofthe filter assembly 98 where any remaining small dust particles aretrapped by the filter media 110 prior to the air being drawn into thevacuum fan/motor assembly 22. Working air is then drawn into the workingair inlet 91, through the fan chamber 89 and is exhausted through theworking air outlet 93. The working air then enters the motor coolinginlet 95, is drawn over the motor assembly 85, thereby reducing itsworking temperature, and is then exhausted through the motor coolingoutlet 97. From the motor cooling outlet 97, the working air travelsthrough the outlet region 96 and is forced through the exhaust filterregion 108 of the filter assembly 98, where any remaining debris orbrush motor dust is trapped in the exhaust filter media 112, and,finally, through the exhaust apertures 116 in the filter cover 114 andinto the external atmosphere.

To dispose of collected dirt and dust, the dirt cup assembly 66 isdetached from the cyclone separator 50 to provide a clear, unobstructedpath for the debris captured in both the first stage collection chamber70 and the second stage collection chamber 72 to be removed. Dust anddirt disposal is accomplished by inverting the dirt cup assembly 66.

Referring to FIGS. 7 and 8, a cyclone module assembly 120 according to afifth embodiment of the invention is shown and comprises an outerhousing 122, a grill assembly 124, an inner housing 162, and a bottomdebris release door 128. The outer housing 122 has an open bottom thatcan be selectively closed by the door 128, a closed top formed by anupper wall 143 and a side wall comprising a lower dirt cup wall 145joined with an upper first stage separation chamber wall 146 via aninward step 148 such that the dirt cup wall 145 has a largercircumference than the first stage separation chamber wall 146. Theinward step extends around the circumference of the housing 122 along anadvancing helical trajectory. The outer housing 122 further comprises aworking air inlet 130 formed in the first stage separation chamber wall146 an outlet 132 formed in the upper wall 143. The outlet 132 can be influid communication with the conduit 94 (FIGS. 5 and 6).

The cyclone module assembly 120 further comprises a first stageseparation chamber 134, a first stage collection chamber 136, a secondstage separation chamber 138, and a second stage collection chamber 140.The first stage cyclone separation chamber 134 is formed between thegrill assembly 124 and the first stage separation chamber wall 146. Afirst stage debris outlet 142 is formed by a gap between a separatorplate 144 mounted on the inner housing 162 and the first stageseparation chamber wall 146. The first stage collection chamber 136 isformed between the inner housing 162 and the dirt cup wall 145. Thejunction between the first stage separation chamber 134 and itscorresponding collection chamber 136 is defined by the inward step 148.In other words, the inward step 148 divides the first stage separationchamber 134 from the collection chamber 136.

The inner housing 162 is positioned between the upper wall 143 and therelease door 128 and comprises a frusto-conical separator 126 and asecond stage debris collector 155 beneath the frusto-conical separator126. The frusto-conical separator 126 defines the second stageseparation chamber 138, which is positioned concentrically and in serieswith the first stage separator chamber 134, and includes an uppercylindrical portion 178, a lower cylindrical portion 180 which mountsthe separator plate 144, and a cone-shaped portion 182 formed betweenthe cylindrical portions 178, 180. A pair of opposed inlets 152 areformed in the upper cylindrical portion 178 and a second debris outlet154 is formed in the lower cylindrical portion 180. The debris outlet154 is fluidly connected to the second stage debris collector 155.

The second stage debris collector 155 comprises a second cone-shapedportion 160 and a debris collection cylinder 156 beneath the cone-shapedportion 160. The cone-shaped portion 160 defines a frusto-conicalchamber 157 that terminates into the cylindrical second stage debriscollection chamber 140, which is defined by the debris collectioncylinder 156. The frusto-conical chamber 157 flares outwardly from thesecond stage debris outlet 154 to create a horizontal step 159 thatextends outwardly from the perimeter of the lower cylindrical portion180. The cone-shaped portion 160 extends downwardly and inwardly fromthe outer edge of the horizontal step 159 and fluidly connects to thedebris collection cylinder 156 on a bottom side thereby joining therespective internal chambers 157 and 140. The bottom surface of thesecond stage debris collection chamber 140 sealingly mates to the debrisrelease door 128 in selective fashion such that the second stage debrisoutlet 154 is isolated from the first stage debris outlet 142. Thesecond stage collection chamber 140 can be formed by a separate secondstage cyclone housing 162, or, alternatively, it can be formed as partof the outer housing 122.

In a preferred embodiment, the debris release door 128 is movablebetween a first and second position. In the first, closed position,shown in FIG. 8, the debris release door 128 is located adjacent to thebottom of the dirt cup wall 145 of the outer housing 122 and forms thebottom wall of the first and second stage collection chambers 136, 140.The door 128 is configured to selectively pivot away from the dirt cupwall 145, thus creating an opening at the bottom side of the first andsecond stage debris collection chambers 136, 140 to allow easy,simultaneous emptying of the outer and inner housings 122, 162.

The operation of the alternate cyclone module assembly 120 will now bedescribed with reference to FIG. 8, in which the flow path of air isindicated by arrows. In operation, the vacuum fan/motor assembly 22 ispositioned downstream of a cyclone outlet 132. When energized, thevacuum fan/motor assembly 22 draws air from the suction nozzle 38 to thecyclone inlet 130 and into the outer housing 122 where the dirty air toswirls around the first stage separation chamber wall 146 of the firststage cyclone separation chamber 134. Larger debris falls into the firststage collection chamber 136. The inward step 148 formed on the cyclonehousing 122 functions to direct or urge the debris to the bottom of thecollection chamber 136 and keep the separated debris contained in thecollection chamber 136. The working air then passes through the grillassembly 124 to filter out any remaining large debris and enters thesecond stage separator 138 via the second stage inlets 152. The secondstage inlets 152 directs the air tangentially and downwardly along aninside surface of the frusto-conical separator 126. The airflow turnsnear the second stage debris outlet 154 and proceeds directly upward andthrough the cyclone outlet 132. The dirt removed by the frusto-conicalseparator 126 falls into the second stage debris collector 155 beneath.

The second stage debris collector 155 collects and retains dirt that isremoved from the working air stream in the inner housing 162 and droppedthrough the second stage outlet 154. The outward flare of the secondfrusto-conical chamber 157 reduces the velocity of the working airstream in the second stage debris collector 155, to preventre-entrainment of dirt in the second stage collection chamber 140. Thehorizontal step 159 provides additional debris re-entrainment preventionby blocking any lingering debris swirling around the inner surface ofthe cone-shaped portion 160 from entering the second stage debris outlet154. The working air continues to travel through the working air conduit94 (FIG. 6) and is delivered to the pre-motor filter region 106 of thefilter assembly 98, as described above, before passing through thevacuum fan/motor assembly 22, the exhaust filter region 108 of thefilter assembly 98 and, finally, into the external atmosphere. Todispose of collected dirt and dust, the debris release door 128 can beselectively pivoted away from the bottom of the dirt cup housing 122 toallow debris to fall out of the first and second collection chambers136, 140 simultaneously.

While the invention has been specifically described in connection withcertain specific embodiments thereof, it is to be understood that thisis by way of illustration and not of limitation. For example, while thecyclone module assemblies illustrated herein are shown having two stagesof separation, it is understood that the improvements to the collectionchamber could be applied to a single stage separator, or other types ofcyclone separators. Reasonable variation and modification are possiblewith the scope of the foregoing disclosure and drawings withoutdeparting from the spirit of the invention which, is defined in theappended claims.

What is claimed is:
 1. A vacuum cleaner comprising: a cyclone separatorhaving a separator chamber for separating contaminants from adirt-containing airstream, and further comprising an inlet and an outletin fluid communication with the separator chamber; a collection chamberassociated with the cyclone separator for receiving contaminantsseparated in the separator chamber and having a sidewall and a bottomwall; a suction nozzle fluidly connected with the inlet; a suctionsource fluidly connected to the suction nozzle and to the separatorchamber for establishing and maintaining a dirt-containing airstreamfrom the suction nozzle to the inlet; and a single circumferential finextending inwardly from the sidewall of the collection chamber, whereinthe fin is configured to reduce debris re-entrainment in the collectionchamber.
 2. The vacuum cleaner according to claim 1 wherein the finextends only partially around the circumference of the collectionchamber and comprises a leading end and a trailing end that isvertically spaced below the leading end.
 3. The vacuum cleaner accordingto claim 1 wherein the fin extends at least 360° around thecircumference of the collection chamber.
 4. The vacuum cleaner accordingto claim 3 wherein the fin extends approximately 360° around thecircumference of the collection chamber and comprises a leading end anda trailing end that lie along a common plane.
 5. The vacuum cleaneraccording to claim 3 wherein the fin has a helical trajectory to directcontaminants toward the bottom wall.
 6. The vacuum cleaner according toclaim 1 wherein the fin has a helical trajectory to direct contaminantstoward the bottom wall.
 7. The vacuum cleaner according to claim 1wherein the fin is attached to the sidewall and comprises spaced firstand second edges extending inwardly from the sidewall and a free endjoined to the first and second edges.
 8. The vacuum cleaner according toclaim 7 wherein the fin is spaced between the bottom wall and an upperend of the collection chamber.
 9. The vacuum cleaner according to claim8, and further comprising a separator plate separating the separatorchamber from the collection chamber, the separator plate defining a gapfor passage of dirt separated from the dirt-containing airstream in theseparator chamber.
 10. The vacuum cleaner according to claim 9 whereinthe fin is spaced below the separator plate.
 11. The vacuum cleaneraccording to claim 1 wherein the cyclone separator further comprises anouter cyclone housing and an inner cyclone housing, wherein theseparator chamber comprises a first stage separator chamber definedbetween the outer and inner cyclone housings, and wherein a second stageseparator chamber is defined within the inner cyclone housing and isfluidly downstream of the first stage separator chamber.
 12. The vacuumcleaner according to claim 11 wherein the collection chamber comprises afirst collection chamber associated with the first stage separatorchamber for receiving contaminants separated in the first stageseparator chamber.
 13. The vacuum cleaner according to claim 12, andfurther comprising a second collection chamber associated with thesecond stage separator chamber for receiving contaminants separated inthe second stage separator chamber, wherein the second collectionchamber is sealed off from the first collection chamber and is spacedinwardly of the fin.
 14. The vacuum cleaner according to claim 11wherein the outer cyclone housing comprises a cylindrical outer wall, anupper wall forming a closed top of the outer cyclone housing, and anopen bottom, wherein the inlet is formed in the outer wall and the openbottom is coupled with the sidewall of the collection chamber.
 15. Thevacuum cleaner according to claim 14 wherein the outlet is formed on theupper wall of the outer cyclone housing.
 16. The vacuum cleaneraccording to claim 14 wherein the inner cyclone housing comprises anupper cylindrical portion that depends from the upper wall of the outercyclone housing and a lower frusto-conical portion.
 17. The vacuumcleaner according to claim 16, and further comprising a pair of opposedair inlets formed in the upper cylindrical portion of the inner cyclonehousing and a debris outlet formed in the bottom of the lowerfrusto-conical portion.
 18. The vacuum cleaner according to claim 16wherein a grill assembly is positioned around the upper cylindricalportion of the inner cyclone housing and separates the first stageseparator chamber from the second stage separator chamber.
 19. Thevacuum cleaner according to claim 1 and further comprising an uprighthandle assembly pivotally mounted to a foot assembly, wherein thecyclone separator and collection chamber are provided on the uprighthandle assembly and the suction nozzle is provided on the foot assembly.